A Jewel at the Heart of Quantum Physics

Artists rendering of the amplituhedron, a newly discovered mathematical object resembling a multifaceted jewel in higher dimensions. Encoded in its volume are the most basic features of reality that can be calculated  the probabilities of outcomes of particle interactions.

Physicists have discovered a jewel-like geometric object that dramatically simplifies calculations of particle interactions and challenges the notion that space and time are fundamental components of reality.

This is completely new and very much simpler than anything that has been done before, said Andrew Hodges, a mathematical physicist at Oxford University who has been following the work.

The revelation that particle interactions, the most basic events in nature, may be consequences of geometry significantly advances a decades-long effort to reformulate quantum field theory, the body of laws describing elementary particles and their interactions. Interactions that were previously calculated with mathematical formulas thousands of terms long can now be described by computing the volume of the corresponding jewel-like amplituhedron, which yields an equivalent one-term expression.

The degree of efficiency is mind-boggling, said Jacob Bourjaily, a theoretical physicist at Harvard University and one of the researchers who developed the new idea. You can easily do, on paper, computations that were infeasible even with a computer before.

The new geometric version of quantum field theory could also facilitate the search for a theory of quantum gravity that would seamlessly connect the large- and small-scale pictures of the universe. Attempts thus far to incorporate gravity into the laws of physics at the quantum scale have run up against nonsensical infinities and deep paradoxes. The amplituhedron, or a similar geometric object, could help by removing two deeply rooted principles of physics: locality and unitarity.

Both are hard-wired in the usual way we think about things, said Nima Arkani-Hamed, a professor of physics at the Institute for Advanced Study in Princeton, N.J., and the lead author of the new work, which he is presenting in talks and in a forthcoming paper. Both are suspect.

Locality is the notion that particles can interact only from adjoining positions in space and time. And unitarity holds that the probabilities of all possible outcomes of a quantum mechanical interaction must add up to one. The concepts are the central pillars of quantum field theory in its original form, but in certain situations involving gravity, both break down, suggesting neither is a fundamental aspect of nature.

In keeping with this idea, the new geometric approach to particle interactions removes locality and unitarity from its starting assumptions. The amplituhedron is not built out of space-time and probabilities; these properties merely arise as consequences of the jewels geometry. The usual picture of space and time, and particles moving around in them, is a construct.

Its a better formulation that makes you think about everything in a completely different way, said David Skinner, a theoretical physicist at Cambridge University.

The amplituhedron itself does not describe gravity. But Arkani-Hamed and his collaborators think there might be a related geometric object that does. Its properties would make it clear why particles appear to exist, and why they appear to move in three dimensions of space and to change over time.

Because we know that ultimately, we need to find a theory that doesnt have unitarity and locality, Bourjaily said, its a starting point to ultimately describing a quantum theory of gravity.

Clunky Machinery

The amplituhedron looks like an intricate, multifaceted jewel in higher dimensions. Encoded in its volume are the most basic features of reality that can be calculated, scattering amplitudes, which represent the likelihood that a certain set of particles will turn into certain other particles upon colliding. These numbers are what particle physicists calculate and test to high precision at particle accelerators like the Large Hadron Collider in Switzerland.

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The iconic 20th century physicist Richard Feynman invented a method for calculating probabilities of particle interactions using depictions of all the different ways an interaction could occur. Examples of Feynman diagrams were included on a 2005 postage stamp honoring Feynman.

The 60-year-old method for calculating scattering amplitudes  a major innovation at the time  was pioneered by the Nobel Prize-winning physicist Richard Feynman. He sketched line drawings of all the ways a scattering process could occur and then summed the likelihoods of the different drawings. The simplest Feynman diagrams look like trees: The particles involved in a collision come together like roots, and the particles that result shoot out like branches. More complicated diagrams have loops, where colliding particles turn into unobservable virtual particles that interact with each other before branching out as real final products. There are diagrams with one loop, two loops, three loops and so on  increasingly baroque iterations of the scattering process that contribute progressively less to its total amplitude. Virtual particles are never observed in nature, but they were considered mathematically necessary for unitarity  the requirement that probabilities sum to one.

The number of Feynman diagrams is so explosively large that even computations of really simple processes werent done until the age of computers, Bourjaily said. A seemingly simple event, such as two subatomic particles called gluons colliding to produce four less energetic gluons (which happens billions of times a second during collisions at the Large Hadron Collider), involves 220 diagrams, which collectively contribute thousands of terms to the calculation of the scattering amplitude.

In 1986, it became apparent that Feynmans apparatus was a Rube Goldberg machine.

To prepare for the construction of the Superconducting Super Collider in Texas (a project that was later canceled), theorists wanted to calculate the scattering amplitudes of known particle interactions to establish a background against which interesting or exotic signals would stand out. But even 2-gluon to 4-gluon processes were so complex, a group of physicists had written two years earlier, that they may not be evaluated in the foreseeable future.

Stephen Parke and Tommy Taylor, theorists at Fermi National Accelerator Laboratory in Illinois, took that statement as a challenge. Using a few mathematical tricks, they managed to simplify the 2-gluon to 4-gluon amplitude calculation from several billion terms to a 9-page-long formula, which a 1980s supercomputer could handle. Then, based on a pattern they observed in the scattering amplitudes of other gluon interactions, Parke and Taylor guessed a simple one-term expression for the amplitude. It was, the computer verified, equivalent to the 9-page formula. In other words, the traditional machinery of quantum field theory, involving hundreds of Feynman diagrams worth thousands of mathematical terms, was obfuscating something much simpler. As Bourjaily put it: Why are you summing up millions of things when the answer is just one function?

We knew at the time that we had an important result, Parke said. We knew it instantly. But what to do with it?

The Amplituhedron

The message of Parke and Taylors single-term result took decades to interpret. That one-term, beautiful little function was like a beacon for the next 30 years, Bourjaily said. It really started this revolution.

Arkani-Hamed et al.

Twistor diagrams depicting an interaction between six gluons, in the cases where two (left) and four (right) of the particles have negative helicity, a property similar to spin. The diagrams can be used to derive a simple formula for the 6-gluon scattering amplitude.

In the mid-2000s, more patterns emerged in the scattering amplitudes of particle interactions, repeatedly hinting at an underlying, coherent mathematical structure behind quantum field theory. Most important was a set of formulas called the BCFW recursion relations, named for Ruth Britto, Freddy Cachazo, Bo Feng and Edward Witten. Instead of describing scattering processes in terms of familiar variables like position and time and depicting them in thousands of Feynman diagrams, the BCFW relations are best couched in terms of strange variables called twistors, and particle interactions can be captured in a handful of associated twistor diagrams. The relations gained rapid adoption as tools for computing scattering amplitudes relevant to experiments, such as collisions at the Large Hadron Collider. But their simplicity was mysterious.

The terms in these BCFW relations were coming from a different world, and we wanted to understand what that world was, Arkani-Hamed said. Thats what drew me into the subject five years ago.

With the help of leading mathematicians such as Pierre Deligne, Arkani-Hamed and his collaborators discovered that the recursion relations and associated twistor diagrams corresponded to a well-known geometric object. In fact, as detailed in a paper posted to arXiv.org in December by Arkani-Hamed, Bourjaily, Cachazo, Alexander Goncharov, Alexander Postnikov and Jaroslav Trnka, the twistor diagrams gave instructions for calculating the volume of pieces of this object, called the positive Grassmannian.

Named for Hermann Grassmann, a 19th-century German linguist and mathematician who studied its properties, the positive Grassmannian is the slightly more grown-up cousin of the inside of a triangle, Arkani-Hamed explained. Just as the inside of a triangle is a region in a two-dimensional space bounded by intersecting lines, the simplest case of the positive Grassmannian is a region in an N-dimensional space bounded by intersecting planes. (N is the number of particles involved in a scattering process.)

It was a geometric representation of real particle data, such as the likelihood that two colliding gluons will turn into four gluons. But something was still missing.

The physicists hoped that the amplitude of a scattering process would emerge purely and inevitably from geometry, but locality and unitarity were dictating which pieces of the positive Grassmannian to add together to get it. They wondered whether the amplitude was the answer to some particular mathematical question, said Trnka, a post-doctoral researcher at the California Institute of Technology. And it is, he said.

Nima Arkani-Hamed

A sketch of the amplituhedron representing an 8-gluon particle interaction. Using Feynman diagrams, the same calculation would take roughly 500 pages of algebra.

Arkani-Hamed and Trnka discovered that the scattering amplitude equals the volume of a brand-new mathematical object  the amplituhedron. The details of a particular scattering process dictate the dimensionality and facets of the corresponding amplituhedron. The pieces of the positive Grassmannian that were being calculated with twistor diagrams and then added together by hand were building blocks that fit together inside this jewel, just as triangles fit together to form a polygon.

Like the twistor diagrams, the Feynman diagrams are another way of computing the volume of the amplituhedron piece by piece, but they are much less efficient. They are local and unitary in space-time, but they are not necessarily very convenient or well-adapted to the shape of this jewel itself, Skinner said. Using Feynman diagrams is like taking a Ming vase and smashing it on the floor.

Arkani-Hamed and Trnka have been able to calculate the volume of the amplituhedron directly in some cases, without using twistor diagrams to compute the volumes of its pieces. They have also found a master amplituhedron with an infinite number of facets, analogous to a circle in 2-D, which has an infinite number of sides. Its volume represents, in theory, the total amplitude of all physical processes. Lower-dimensional amplituhedra, which correspond to interactions between finite numbers of particles, live on the faces of this master structure.

They are very powerful calculational techniques, but they are also incredibly suggestive, Skinner said. They suggest that thinking in terms of space-time was not the right way of going about this.

Quest for Quantum Gravity

The seemingly irreconcilable conflict between gravity and quantum field theory enters crisis mode in black holes. Black holes pack a huge amount of mass into an extremely small space, making gravity a major player at the quantum scale, where it can usually be ignored. Inevitably, either locality or unitarity is the source of the conflict.

Puzzling Thoughts

Locality and unitarity are the central pillars of quantum field theory, but as the following thought experiments show, both break down in certain situations involving gravity. This suggests physics should be formulated without either principle.

Locality says that particles interact at points in space-time. But suppose you want to inspect space-time very closely. Probing smaller and smaller distance scales requires ever higher energies, but at a certain scale, called the Planck length, the picture gets blurry: So much energy must be concentrated into such a small region that the energy collapses the region into a black hole, making it impossible to inspect. Theres no way of measuring space and time separations once they are smaller than the Planck length, said Arkani-Hamed. So we imagine space-time is a continuous thing, but because its impossible to talk sharply about that thing, then that suggests it must not be fundamental  it must be emergent.

Unitarity says the quantum mechanical probabilities of all possible outcomes of a particle interaction must sum to one. To prove it, one would have to observe the same interaction over and over and count the frequencies of the different outcomes. Doing this to perfect accuracy would require an infinite number of observations using an infinitely large measuring apparatus, but the latter would again cause gravitational collapse into a black hole. In finite regions of the universe, unitarity can therefore only be approximately known.

We have indications that both ideas have got to go, Arkani-Hamed said. They cant be fundamental features of the next description, such as a theory of quantum gravity.

String theory, a framework that treats particles as invisibly small, vibrating strings, is one candidate for a theory of quantum gravity that seems to hold up in black hole situations, but its relationship to reality is unproven  or at least confusing. Recently, a strange duality has been found between string theory and quantum field theory, indicating that the former (which includes gravity) is mathematically equivalent to the latter (which does not) when the two theories describe the same event as if it is taking place in different numbers of dimensions. No one knows quite what to make of this discovery. But the new amplituhedron research suggests space-time, and therefore dimensions, may be illusory anyway.

We cant rely on the usual familiar quantum mechanical space-time pictures of describing physics, Arkani-Hamed said. We have to learn new ways of talking about it. This work is a baby step in that direction.

Even without unitarity and locality, the amplituhedron formulation of quantum field theory does not yet incorporate gravity. But researchers are working on it. They say scattering processes that include gravity particles may be possible to describe with the amplituhedron, or with a similar geometric object. It might be closely related but slightly different and harder to find, Skinner said.

Courtesy of Jaroslav Trnka

Nima Arkani-Hamed, a professor at the Institute for Advanced Study, and his former student and co-author Jaroslav Trnka, who finished his Ph.D. at Princeton University in July and is now a post-doctoral researcher at the California Institute of Technology.

Physicists must also prove that the new geometric formulation applies to the exact particles that are known to exist in the universe, rather than to the idealized quantum field theory they used to develop it, called maximally supersymmetric Yang-Mills theory. This model, which includes a superpartner particle for every known particle and treats space-time as flat, just happens to be the simplest test case for these new tools, Bourjaily said. The way to generalize these new tools to [other] theories is understood.

Beyond making calculations easier or possibly leading the way to quantum gravity, the discovery of the amplituhedron could cause an even more profound shift, Arkani-Hamed said. That is, giving up space and time as fundamental constituents of nature and figuring out how the Big Bang and cosmological evolution of the universe arose out of pure geometry.

In a sense, we would see that change arises from the structure of the object, he said. But its not from the object changing. The object is basically timeless.

While more work is needed, many theoretical physicists are paying close attention to the new ideas.

The work is very unexpected from several points of view, said Witten, a theoretical physicist at the Institute for Advanced Study. The field is still developing very fast, and it is difficult to guess what will happen or what the lessons will turn out to be.

I don’t pretend to understand everything in the article, but it sure sounds fascinating.

Seems like everything we think we know about reality is actually an illusion (or “emergent”, to use their term).

It’s bad enough being a temporary miniscule speck of dust in an infinite universe. Now we’re temporary miniscule specks of dust in an infinite universe that’s just a construct of a completely different reality we can only dimly grasp.

Puts the headache I have this morning into a little different persective.

“They are very powerful calculational techniques, but they are also incredibly suggestive, Skinner said. They suggest that thinking in terms of space-time was not the right way of going about this.
++++++++++++++++
If this doesn’t get your attention then you haven’t been following the last 100 year of progress in our attempt to unravel the secrets of nature.

This could be revolutionary. I hope so.

And I wonder how this impacts current String Theory. A confirmation perhaps or, like the Feynman diagram, no longer useful.

i guess more than discovering... identifying... physicists new something was there... that which they couldn’t explain... discovering something that was there, like north america in colombus days, ignorance of its existance, doesn’t grant a “discovery” but a realization of its identity.

men of faith knew of God’s touch, but couldn’t specifically identify it.

teeman

15
posted on 09/19/2013 6:47:27 AM PDT
by teeman8r
(Armageddon won't be pretty, but it's not like it's the end of the world.)

Agreed. I often wonder how much is lost in the process of simplifying it.

Incredible find, that the sum of multiple approaches toward solving a problem, turns out to be an overall effort to arrive at the volume of a geometric body.

Indeed. It would be interesting as well to look at this geometry from a perspective of how such an object would unfold. Just about any geometric shape can ultimately be folded flat. Maybe thats where we live.

I also love that fact that the object in question looks fractal, and indeed seems to have fractal properties judging from the description. I've long thought that the universe itself could be described by what is probably a fairly short fractal equation. God, it is readily apparent to me anyway, seems to have a sense of humor, and this would fit right in with that.

Nima Arkani-Hamed is a professor of physics at Harvard University. His father is a physicist who openly spoke against the Iranian Revolutionary Guard after the Iranian revolution in 1979. In fear for their lives, his family fled through the Turkish border on horseback in 1981, tearing up their passports as they cross the border. Nima's family emigrated to Canada where Nima finished high school and attended the University of Toronto as an undergraduate. He received is Ph.D. from Berkeley in 1997 and took a research position at Stanford before moving back to Berkeley two years later for a faculty position. The return was short-lived as Harvard snatched him up in 2001.

Nima is considered the greatest theoretical particle physicist of his generation. Despite his youth, he has become a leader in the field, creating subfields with each new idea. He now splits his time between studying fundamental issues with quantum theories of gravity and hands-on contributions to understanding in detail what we see at the LHC.

I'm thrilled to see this shift from the Kaluza/Klein compactification models (string theory et al) to higher dimensional dynamics.

Another recent article was considering higher dimensional geometry in lieu of the big bang/inflationary model. And this particular article is running directly towards Max Tegmark's Level IV parallel universe model, roughly that what we experience in 4D is a manifestation of mathematical structures which actually do exist outside of space and time.

P.S. Wesson is a pioneer physicist in higher dimensional dynamics. His theories suggest a higher time-like dimension, that what we observe as reality in 4D could be as little as a single particle in a higher dimension, multiply imaged 1080 times.

And, of course, he also proposed that physical death in that geometry could simply be a phase shift.

I just keep thinking, “If they continue to tumble this problem around, they will eventually see it as the effect of phase shifts in the variable expressions of dimension space and dimension time, causing the ‘tensions’ between the expressed continua and the about to be expressed” ... but then, I'm a dreamer, and my tensor calculus is not so sharp anymore.

I'm thrilled to see this shift from the Kaluza/Klein compactification models (string theory et al) to higher dimensional dynamics.

Me too!!!

I'm fascinated by the ideas that space and time are not "fundamental" properties of the universe; rather they are emergent properties; and that locality and unitarity are not fundamental aspects of nature. Also that the amplituhedron geometry hints "at an underlying, coherent mathematical structure behind quantum field theory," indeed behind/beyond 4D spacetime itself.

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